Intelligent Rotary Steerable System, Coupled with an Instrumented Bit, Delivers Section Plan in Deepwater GOM Project

J. Snyder, G. Salmon
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Abstract

The challenging offshore drilling environment has increased the need for cost-effective operations to deliver accurate well placement, high borehole quality, and shoe-to-shoe drilling performance. As well construction complexity continues to develop, the need for an improved systems approach to delivering integrated performance is critical. Complex bottom hole assemblies (BHA) used in deepwater operations will include additional sensors and capabilities than in the past. These BHAs consist of multiple cutting structures (bit/reamer), gamma, resistivity, density, porosity, sonic, formation pressure testing/sampling capabilities, as well as drilling dynamics systems and onboard diagnostic sensors. Rock cutting structure design primarily relied on data capture at the surface. An instrumented sensor package within the drill bit provides dynamic measurements allowing for better understanding of BHA performance, creating a more efficient system for all drilling conditions. The addition of intelligent systems that monitor and control these complex BHAs, makes it possible to implement autonomous steering of directional drilling assemblies in the offshore environment. In the Deepwater Gulf of Mexico (GOM), this case study documents the introduction of a new automated drilling service and Intelligent Rotary Steerable System (iRSS) with an instrumented bit. Utilizing these complex BHAs, the system can provide real-time (RT) steering decisions automatically given the downhole tool configuration, planned well path, and RT sensor information received. The 6-3/4-inch nominal diameter system, coupled with the instrumented bit, successfully completed the first 5,400-foot (1,650m) section while enlarging the 8-1/2-inch (216mm) borehole to 9-7/8 inches (250mm). The system delivered a high-quality wellbore with low tortuosity and minimal vibration, while keeping to the planned well path. The system achieved all performance objectives and captured dynamic drilling responses for use in an additional applications. This fast sampling iRSS maintains continuous and faster steering control at high rates of penetration (ROP) providing accurate well path directional control. The system-matched polycrystalline diamond (PDC) bit is engineered to deliver greater side cutting efficiency with enhanced cutting structure improving the iRSS performance. Included within the bit is an instrumentation package that tracks drilling dynamics at the bit. The bit dynamics data is then used to improve bit designs and optimize drilling parameters.
智能旋转导向系统与仪器钻头相结合,为深水钻井项目提供分段方案
具有挑战性的海上钻井环境增加了对具有成本效益的作业的需求,以提供准确的井位,高井眼质量和鞋对鞋的钻井性能。随着构造复杂性的不断发展,需要改进系统方法来提供集成性能是至关重要的。与过去相比,用于深水作业的复杂底部钻具组合(BHA)将包括更多的传感器和功能。这些bha包括多种切削结构(钻头/扩眼器)、伽马、电阻率、密度、孔隙度、声波、地层压力测试/采样能力,以及钻井动力学系统和机载诊断传感器。岩石切割结构的设计主要依赖于地面的数据采集。钻头内的仪表传感器包提供动态测量,从而更好地了解底部钻具组合的性能,为所有钻井条件创造更高效的系统。通过添加智能系统来监测和控制这些复杂的bha,可以在海上环境中实现定向钻井组合的自主转向。在墨西哥湾深水(GOM),本案例研究记录了一种新的自动化钻井服务和智能旋转导向系统(iRSS)与仪器钻头的结合。利用这些复杂的bha,系统可以根据井下工具配置、计划井眼轨迹和接收到的RT传感器信息,自动提供实时(RT)转向决策。6-3/4英寸的公称直径系统,加上仪器钻头,成功完成了第一个5400英尺(1650m)的井段,同时将8-1/2英寸(216mm)的井眼扩大到9-7/8英寸(250mm)。该系统提供了高质量的井眼,弯曲度低,振动最小,同时保持了计划的井眼轨迹。该系统实现了所有性能目标,并捕获了动态钻井响应,可用于其他应用。这种快速采样iRSS在高钻速(ROP)下保持连续和更快的转向控制,提供精确的井眼轨迹定向控制。系统匹配的聚晶金刚石(PDC)钻头通过改进的切削结构提高了iRSS性能,从而提高了侧向切削效率。该钻头包含一个仪器包,用于跟踪钻头的钻井动态。然后利用钻头动力学数据改进钻头设计并优化钻井参数。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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